/* $OpenBSD: relayd.c,v 1.89 2009/06/05 23:39:51 pyr Exp $ */ /* * Copyright (c) 2007, 2008 Reyk Floeter * Copyright (c) 2006 Pierre-Yves Ritschard * * Permission to use, copy, modify, and distribute this software for any * purpose with or without fee is hereby granted, provided that the above * copyright notice and this permission notice appear in all copies. * * THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES * WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF * MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR * ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES * WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN * ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF * OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "relayd.h" __dead void usage(void); void main_sig_handler(int, short, void *); void main_shutdown(struct relayd *); void main_dispatch_pfe(int, short, void *); void main_dispatch_hce(int, short, void *); void main_dispatch_relay(int, short, void *); int check_child(pid_t, const char *); int send_all(struct relayd *, enum imsg_type, void *, u_int16_t); void reconfigure(void); void purge_tree(struct proto_tree *); int bindany(struct ctl_bindany *); int pipe_parent2pfe[2]; int pipe_parent2hce[2]; int pipe_pfe2hce[2]; int pipe_parent2relay[RELAY_MAXPROC][2]; int pipe_pfe2relay[RELAY_MAXPROC][2]; struct relayd *relayd_env; struct imsgev *iev_pfe; struct imsgev *iev_hce; struct imsgev *iev_relay; pid_t pfe_pid = 0; pid_t hce_pid = 0; pid_t relay_pid = 0; void main_sig_handler(int sig, short event, void *arg) { struct relayd *env = arg; int die = 0; switch (sig) { case SIGTERM: case SIGINT: die = 1; /* FALLTHROUGH */ case SIGCHLD: if (check_child(pfe_pid, "pf update engine")) { pfe_pid = 0; die = 1; } if (check_child(hce_pid, "host check engine")) { hce_pid = 0; die = 1; } if (check_child(relay_pid, "socket relay engine")) { relay_pid = 0; die = 1; } if (die) main_shutdown(env); break; case SIGHUP: reconfigure(); break; default: fatalx("unexpected signal"); } } /* __dead is for lint */ __dead void usage(void) { extern char *__progname; fprintf(stderr, "usage: %s [-dnv] [-D macro=value] [-f file]\n", __progname); exit(1); } int main(int argc, char *argv[]) { int c; int debug; u_int32_t opts; struct relayd *env; const char *conffile; struct event ev_sigint; struct event ev_sigterm; struct event ev_sigchld; struct event ev_sighup; struct imsgev *iev; opts = 0; debug = 0; conffile = CONF_FILE; log_init(1); /* log to stderr until daemonized */ while ((c = getopt(argc, argv, "dD:nf:v")) != -1) { switch (c) { case 'd': debug = 2; break; case 'D': if (cmdline_symset(optarg) < 0) log_warnx("could not parse macro definition %s", optarg); break; case 'n': debug = 2; opts |= RELAYD_OPT_NOACTION; break; case 'f': conffile = optarg; break; case 'v': opts |= RELAYD_OPT_VERBOSE; break; default: usage(); } } argc -= optind; argv += optind; if (argc > 0) usage(); if ((env = parse_config(conffile, opts)) == NULL) exit(1); relayd_env = env; if (env->sc_opts & RELAYD_OPT_NOACTION) { fprintf(stderr, "configuration OK\n"); exit(0); } if (debug) env->sc_opts |= RELAYD_OPT_LOGUPDATE; if (geteuid()) errx(1, "need root privileges"); if (getpwnam(RELAYD_USER) == NULL) errx(1, "unknown user %s", RELAYD_USER); log_init(debug); if (!debug) { if (daemon(1, 0) == -1) err(1, "failed to daemonize"); } log_info("startup"); if (socketpair(AF_UNIX, SOCK_STREAM, PF_UNSPEC, pipe_parent2pfe) == -1) fatal("socketpair"); if (socketpair(AF_UNIX, SOCK_STREAM, PF_UNSPEC, pipe_parent2hce) == -1) fatal("socketpair"); if (socketpair(AF_UNIX, SOCK_STREAM, PF_UNSPEC, pipe_pfe2hce) == -1) fatal("socketpair"); for (c = 0; c < env->sc_prefork_relay; c++) { if (socketpair(AF_UNIX, SOCK_STREAM, PF_UNSPEC, pipe_parent2relay[c]) == -1) fatal("socketpair"); if (socketpair(AF_UNIX, SOCK_STREAM, PF_UNSPEC, pipe_pfe2relay[c]) == -1) fatal("socketpair"); session_socket_blockmode(pipe_pfe2relay[c][0], BM_NONBLOCK); session_socket_blockmode(pipe_pfe2relay[c][1], BM_NONBLOCK); session_socket_blockmode(pipe_parent2relay[c][0], BM_NONBLOCK); session_socket_blockmode(pipe_parent2relay[c][1], BM_NONBLOCK); } session_socket_blockmode(pipe_parent2pfe[0], BM_NONBLOCK); session_socket_blockmode(pipe_parent2pfe[1], BM_NONBLOCK); session_socket_blockmode(pipe_parent2hce[0], BM_NONBLOCK); session_socket_blockmode(pipe_parent2hce[1], BM_NONBLOCK); session_socket_blockmode(pipe_pfe2hce[0], BM_NONBLOCK); session_socket_blockmode(pipe_pfe2hce[1], BM_NONBLOCK); pfe_pid = pfe(env, pipe_parent2pfe, pipe_parent2hce, pipe_parent2relay, pipe_pfe2hce, pipe_pfe2relay); hce_pid = hce(env, pipe_parent2pfe, pipe_parent2hce, pipe_parent2relay, pipe_pfe2hce, pipe_pfe2relay); if (env->sc_prefork_relay > 0) relay_pid = relay(env, pipe_parent2pfe, pipe_parent2hce, pipe_parent2relay, pipe_pfe2hce, pipe_pfe2relay); setproctitle("parent"); event_init(); signal_set(&ev_sigint, SIGINT, main_sig_handler, env); signal_set(&ev_sigterm, SIGTERM, main_sig_handler, env); signal_set(&ev_sigchld, SIGCHLD, main_sig_handler, env); signal_set(&ev_sighup, SIGHUP, main_sig_handler, env); signal_add(&ev_sigint, NULL); signal_add(&ev_sigterm, NULL); signal_add(&ev_sigchld, NULL); signal_add(&ev_sighup, NULL); signal(SIGPIPE, SIG_IGN); close(pipe_parent2pfe[1]); close(pipe_parent2hce[1]); close(pipe_pfe2hce[0]); close(pipe_pfe2hce[1]); for (c = 0; c < env->sc_prefork_relay; c++) { close(pipe_pfe2relay[c][0]); close(pipe_pfe2relay[c][1]); close(pipe_parent2relay[c][0]); } if ((iev_pfe = calloc(1, sizeof(struct imsgev))) == NULL || (iev_hce = calloc(1, sizeof(struct imsgev))) == NULL) fatal(NULL); if (env->sc_prefork_relay > 0) { if ((iev_relay = calloc(env->sc_prefork_relay, sizeof(struct imsgev))) == NULL) fatal(NULL); } imsg_init(&iev_pfe->ibuf, pipe_parent2pfe[0]); imsg_init(&iev_hce->ibuf, pipe_parent2hce[0]); iev_pfe->handler = main_dispatch_pfe; iev_hce->handler = main_dispatch_hce; for (c = 0; c < env->sc_prefork_relay; c++) { iev = &iev_relay[c]; imsg_init(&iev->ibuf, pipe_parent2relay[c][1]); iev->handler = main_dispatch_relay; iev->events = EV_READ; event_set(&iev->ev, iev->ibuf.fd, iev->events, iev->handler, iev); event_add(&iev->ev, NULL); } iev_pfe->events = EV_READ; event_set(&iev_pfe->ev, iev_pfe->ibuf.fd, iev_pfe->events, iev_pfe->handler, iev_pfe); event_add(&iev_pfe->ev, NULL); iev_hce->events = EV_READ; event_set(&iev_hce->ev, iev_hce->ibuf.fd, iev_hce->events, iev_hce->handler, iev_hce); event_add(&iev_hce->ev, NULL); if (env->sc_flags & F_DEMOTE) carp_demote_reset(env->sc_demote_group, 0); event_dispatch(); return (0); } void main_shutdown(struct relayd *env) { pid_t pid; if (pfe_pid) kill(pfe_pid, SIGTERM); if (hce_pid) kill(hce_pid, SIGTERM); if (relay_pid) kill(relay_pid, SIGTERM); do { if ((pid = wait(NULL)) == -1 && errno != EINTR && errno != ECHILD) fatal("wait"); } while (pid != -1 || (pid == -1 && errno == EINTR)); control_cleanup(); carp_demote_shutdown(); if (env->sc_flags & F_DEMOTE) carp_demote_reset(env->sc_demote_group, 128); log_info("terminating"); exit(0); } int check_child(pid_t pid, const char *pname) { int status; if (waitpid(pid, &status, WNOHANG) > 0) { if (WIFEXITED(status)) { log_warnx("check_child: lost child: %s exited", pname); return (1); } if (WIFSIGNALED(status)) { log_warnx("check_child: lost child: %s terminated; " "signal %d", pname, WTERMSIG(status)); return (1); } } return (0); } int send_all(struct relayd *env, enum imsg_type type, void *buf, u_int16_t len) { int i; if (imsg_compose_event(iev_pfe, type, 0, 0, -1, buf, len) == -1) return (-1); if (imsg_compose_event(iev_hce, type, 0, 0, -1, buf, len) == -1) return (-1); for (i = 0; i < env->sc_prefork_relay; i++) { if (imsg_compose_event(&iev_relay[i], type, 0, 0, -1, buf, len) == -1) return (-1); } return (0); } void merge_config(struct relayd *env, struct relayd *new_env) { env->sc_opts = new_env->sc_opts; env->sc_flags = new_env->sc_flags; env->sc_confpath = new_env->sc_confpath; env->sc_tablecount = new_env->sc_tablecount; env->sc_rdrcount = new_env->sc_rdrcount; env->sc_protocount = new_env->sc_protocount; env->sc_relaycount = new_env->sc_relaycount; memcpy(&env->sc_interval, &new_env->sc_interval, sizeof(env->sc_interval)); memcpy(&env->sc_timeout, &new_env->sc_timeout, sizeof(env->sc_timeout)); memcpy(&env->sc_empty_table, &new_env->sc_empty_table, sizeof(env->sc_empty_table)); memcpy(&env->sc_proto_default, &new_env->sc_proto_default, sizeof(env->sc_proto_default)); env->sc_prefork_relay = new_env->sc_prefork_relay; (void)strlcpy(env->sc_demote_group, new_env->sc_demote_group, sizeof(env->sc_demote_group)); env->sc_tables = new_env->sc_tables; env->sc_rdrs = new_env->sc_rdrs; env->sc_relays = new_env->sc_relays; env->sc_protos = new_env->sc_protos; } void reconfigure(void) { struct relayd *env = relayd_env; struct relayd *new_env = NULL; struct rdr *rdr; struct address *virt; struct table *table; struct host *host; log_info("reloading configuration"); if ((new_env = parse_config(env->sc_confpath, env->sc_opts)) == NULL) { log_warnx("configuration reloading FAILED"); return; } if (!(env->sc_flags & F_NEEDPF) && (new_env->sc_flags & F_NEEDPF)) { log_warnx("new configuration requires pf while it " "was previously disabled." "configuration will not be reloaded"); purge_config(new_env, PURGE_EVERYTHING); free(new_env); return; } purge_config(env, PURGE_EVERYTHING); merge_config(env, new_env); free(new_env); log_info("configuration merge done"); /* * first reconfigure pfe */ imsg_compose_event(iev_pfe, IMSG_RECONF, 0, 0, -1, env, sizeof(*env)); TAILQ_FOREACH(table, env->sc_tables, entry) { imsg_compose_event(iev_pfe, IMSG_RECONF_TABLE, 0, 0, -1, &table->conf, sizeof(table->conf)); TAILQ_FOREACH(host, &table->hosts, entry) { imsg_compose_event(iev_pfe, IMSG_RECONF_HOST, 0, 0, -1, &host->conf, sizeof(host->conf)); } } TAILQ_FOREACH(rdr, env->sc_rdrs, entry) { imsg_compose_event(iev_pfe, IMSG_RECONF_RDR, 0, 0, -1, &rdr->conf, sizeof(rdr->conf)); TAILQ_FOREACH(virt, &rdr->virts, entry) imsg_compose_event(iev_pfe, IMSG_RECONF_VIRT, 0, 0, -1, virt, sizeof(*virt)); } imsg_compose_event(iev_pfe, IMSG_RECONF_END, 0, 0, -1, NULL, 0); /* * then reconfigure hce */ imsg_compose_event(iev_hce, IMSG_RECONF, 0, 0, -1, env, sizeof(*env)); TAILQ_FOREACH(table, env->sc_tables, entry) { imsg_compose_event(iev_hce, IMSG_RECONF_TABLE, 0, 0, -1, &table->conf, sizeof(table->conf)); if (table->sendbuf != NULL) imsg_compose_event(iev_hce, IMSG_RECONF_SENDBUF, 0, 0, -1, table->sendbuf, strlen(table->sendbuf) + 1); TAILQ_FOREACH(host, &table->hosts, entry) { imsg_compose_event(iev_hce, IMSG_RECONF_HOST, 0, 0, -1, &host->conf, sizeof(host->conf)); } } imsg_compose_event(iev_hce, IMSG_RECONF_END, 0, 0, -1, NULL, 0); } void purge_config(struct relayd *env, u_int8_t what) { struct table *table; struct rdr *rdr; struct address *virt; struct protocol *proto; struct relay *rlay; struct session *sess; if (what & PURGE_TABLES && env->sc_tables != NULL) { while ((table = TAILQ_FIRST(env->sc_tables)) != NULL) purge_table(env->sc_tables, table); free(env->sc_tables); env->sc_tables = NULL; } if (what & PURGE_RDRS && env->sc_rdrs != NULL) { while ((rdr = TAILQ_FIRST(env->sc_rdrs)) != NULL) { TAILQ_REMOVE(env->sc_rdrs, rdr, entry); while ((virt = TAILQ_FIRST(&rdr->virts)) != NULL) { TAILQ_REMOVE(&rdr->virts, virt, entry); free(virt); } free(rdr); } free(env->sc_rdrs); env->sc_rdrs = NULL; } if (what & PURGE_RELAYS && env->sc_relays != NULL) { while ((rlay = TAILQ_FIRST(env->sc_relays)) != NULL) { TAILQ_REMOVE(env->sc_relays, rlay, rl_entry); while ((sess = SPLAY_ROOT(&rlay->rl_sessions)) != NULL) { SPLAY_REMOVE(session_tree, &rlay->rl_sessions, sess); free(sess); } if (rlay->rl_bev != NULL) bufferevent_free(rlay->rl_bev); if (rlay->rl_dstbev != NULL) bufferevent_free(rlay->rl_dstbev); if (rlay->rl_ssl_ctx != NULL) SSL_CTX_free(rlay->rl_ssl_ctx); free(rlay); } free(env->sc_relays); env->sc_relays = NULL; } if (what & PURGE_PROTOS && env->sc_protos != NULL) { while ((proto = TAILQ_FIRST(env->sc_protos)) != NULL) { TAILQ_REMOVE(env->sc_protos, proto, entry); purge_tree(&proto->request_tree); purge_tree(&proto->response_tree); if (proto->style != NULL) free(proto->style); free(proto); } free(env->sc_protos); env->sc_protos = NULL; } } void purge_tree(struct proto_tree *tree) { struct protonode *proot, *pn; while ((proot = RB_ROOT(tree)) != NULL) { RB_REMOVE(proto_tree, tree, proot); if (proot->key != NULL) free(proot->key); if (proot->value != NULL) free(proot->value); while ((pn = SIMPLEQ_FIRST(&proot->head)) != NULL) { SIMPLEQ_REMOVE_HEAD(&proot->head, entry); if (pn->key != NULL) free(pn->key); if (pn->value != NULL) free(pn->value); if (pn->label != 0) pn_unref(pn->label); free(pn); } free(proot); } } void purge_table(struct tablelist *head, struct table *table) { struct host *host; while ((host = TAILQ_FIRST(&table->hosts)) != NULL) { TAILQ_REMOVE(&table->hosts, host, entry); if (host->cte.ssl != NULL) SSL_free(host->cte.ssl); free(host); } if (table->sendbuf != NULL) free(table->sendbuf); if (table->conf.flags & F_SSL) SSL_CTX_free(table->ssl_ctx); if (head != NULL) TAILQ_REMOVE(head, table, entry); free(table); } void imsg_event_add(struct imsgev *iev) { if (iev->handler == NULL) { imsg_flush(&iev->ibuf); return; } iev->events = EV_READ; if (iev->ibuf.w.queued) iev->events |= EV_WRITE; event_del(&iev->ev); event_set(&iev->ev, iev->ibuf.fd, iev->events, iev->handler, iev); event_add(&iev->ev, NULL); } int imsg_compose_event(struct imsgev *iev, u_int16_t type, u_int32_t peerid, pid_t pid, int fd, void *data, u_int16_t datalen) { int ret; if ((ret = imsg_compose(&iev->ibuf, type, peerid, pid, fd, data, datalen)) != -1) imsg_event_add(iev); return (ret); } void main_dispatch_pfe(int fd, short event, void *ptr) { struct imsgev *iev; struct imsgbuf *ibuf; struct imsg imsg; ssize_t n; struct ctl_demote demote; iev = ptr; ibuf = &iev->ibuf; if (event & EV_READ) { if ((n = imsg_read(ibuf)) == -1) fatal("imsg_read_error"); if (n == 0) { /* this pipe is dead, so remove the event handler */ event_del(&iev->ev); event_loopexit(NULL); return; } } if (event & EV_WRITE) { if (msgbuf_write(&ibuf->w) == -1) fatal("msgbuf_write"); } for (;;) { if ((n = imsg_get(ibuf, &imsg)) == -1) fatal("main_dispatch_pfe: imsg_read error"); if (n == 0) break; switch (imsg.hdr.type) { case IMSG_DEMOTE: if (imsg.hdr.len - IMSG_HEADER_SIZE != sizeof(demote)) fatalx("main_dispatch_pfe: " "invalid size of demote request"); memcpy(&demote, imsg.data, sizeof(demote)); carp_demote_set(demote.group, demote.level); break; case IMSG_CTL_RELOAD: /* * so far we only get here if no L7 (relay) is done. */ reconfigure(); break; default: log_debug("main_dispatch_pfe: unexpected imsg %d", imsg.hdr.type); break; } imsg_free(&imsg); } imsg_event_add(iev); } void main_dispatch_hce(int fd, short event, void * ptr) { struct imsgev *iev; struct imsgbuf *ibuf; struct imsg imsg; ssize_t n; struct ctl_script scr; struct relayd *env; env = relayd_env; iev = ptr; ibuf = &iev->ibuf; if (event & EV_READ) { if ((n = imsg_read(ibuf)) == -1) fatal("imsg_read error"); if (n == 0) { /* this pipe is dead, so remove the event handler */ event_del(&iev->ev); event_loopexit(NULL); return; } } if (event & EV_WRITE) { if (msgbuf_write(&ibuf->w) == -1) fatal("msgbuf_write"); } for (;;) { if ((n = imsg_get(ibuf, &imsg)) == -1) fatal("main_dispatch_hce: imsg_read error"); if (n == 0) break; switch (imsg.hdr.type) { case IMSG_SCRIPT: if (imsg.hdr.len - IMSG_HEADER_SIZE != sizeof(scr)) fatalx("main_dispatch_hce: " "invalid size of script request"); bcopy(imsg.data, &scr, sizeof(scr)); scr.retval = script_exec(env, &scr); imsg_compose_event(iev_hce, IMSG_SCRIPT, 0, 0, -1, &scr, sizeof(scr)); break; case IMSG_SNMPSOCK: (void)snmp_sendsock(iev); break; default: log_debug("main_dispatch_hce: unexpected imsg %d", imsg.hdr.type); break; } imsg_free(&imsg); } imsg_event_add(iev); } void main_dispatch_relay(int fd, short event, void * ptr) { struct relayd *env = relayd_env; struct imsgev *iev; struct imsgbuf *ibuf; struct imsg imsg; ssize_t n; struct ctl_bindany bnd; int s; iev = ptr; ibuf = &iev->ibuf; if (event & EV_READ) { if ((n = imsg_read(ibuf)) == -1) fatal("imsg_read error"); if (n == 0) { /* this pipe is dead, so remove the event handler */ event_del(&iev->ev); event_loopexit(NULL); return; } } if (event & EV_WRITE) { if (msgbuf_write(&ibuf->w) == -1) fatal("msgbuf_write"); } for (;;) { if ((n = imsg_get(ibuf, &imsg)) == -1) fatal("main_dispatch_relay: imsg_read error"); if (n == 0) break; switch (imsg.hdr.type) { case IMSG_BINDANY: if (imsg.hdr.len != IMSG_HEADER_SIZE + sizeof(bnd)) fatalx("invalid imsg header len"); bcopy(imsg.data, &bnd, sizeof(bnd)); if (bnd.bnd_proc > env->sc_prefork_relay) fatalx("pfe_dispatch_relay: " "invalid relay proc"); switch (bnd.bnd_proto) { case IPPROTO_TCP: case IPPROTO_UDP: break; default: fatalx("pfe_dispatch_relay: requested socket " "for invalid protocol"); /* NOTREACHED */ } s = bindany(&bnd); imsg_compose_event(&iev_relay[bnd.bnd_proc], IMSG_BINDANY, 0, 0, s, &bnd.bnd_id, sizeof(bnd.bnd_id)); break; default: log_debug("main_dispatch_relay: unexpected imsg %d", imsg.hdr.type); break; } imsg_free(&imsg); } imsg_event_add(iev); } struct host * host_find(struct relayd *env, objid_t id) { struct table *table; struct host *host; TAILQ_FOREACH(table, env->sc_tables, entry) TAILQ_FOREACH(host, &table->hosts, entry) if (host->conf.id == id) return (host); return (NULL); } struct table * table_find(struct relayd *env, objid_t id) { struct table *table; TAILQ_FOREACH(table, env->sc_tables, entry) if (table->conf.id == id) return (table); return (NULL); } struct rdr * rdr_find(struct relayd *env, objid_t id) { struct rdr *rdr; TAILQ_FOREACH(rdr, env->sc_rdrs, entry) if (rdr->conf.id == id) return (rdr); return (NULL); } struct relay * relay_find(struct relayd *env, objid_t id) { struct relay *rlay; TAILQ_FOREACH(rlay, env->sc_relays, rl_entry) if (rlay->rl_conf.id == id) return (rlay); return (NULL); } struct session * session_find(struct relayd *env, objid_t id) { struct relay *rlay; struct session *con; TAILQ_FOREACH(rlay, env->sc_relays, rl_entry) SPLAY_FOREACH(con, session_tree, &rlay->rl_sessions) if (con->se_id == id) return (con); return (NULL); } struct host * host_findbyname(struct relayd *env, const char *name) { struct table *table; struct host *host; TAILQ_FOREACH(table, env->sc_tables, entry) TAILQ_FOREACH(host, &table->hosts, entry) if (strcmp(host->conf.name, name) == 0) return (host); return (NULL); } struct table * table_findbyname(struct relayd *env, const char *name) { struct table *table; TAILQ_FOREACH(table, env->sc_tables, entry) if (strcmp(table->conf.name, name) == 0) return (table); return (NULL); } struct table * table_findbyconf(struct relayd *env, struct table *tb) { struct table *table; struct table_config a, b; bcopy(&tb->conf, &a, sizeof(a)); a.id = a.rdrid = 0; a.flags &= ~(F_USED|F_BACKUP); TAILQ_FOREACH(table, env->sc_tables, entry) { bcopy(&table->conf, &b, sizeof(b)); b.id = b.rdrid = 0; b.flags &= ~(F_USED|F_BACKUP); /* * Compare two tables and return the existing table if * the configuration seems to be the same. */ if (bcmp(&a, &b, sizeof(b)) == 0 && ((tb->sendbuf == NULL && table->sendbuf == NULL) || (tb->sendbuf != NULL && table->sendbuf != NULL && strcmp(tb->sendbuf, table->sendbuf) == 0))) return (table); } return (NULL); } struct rdr * rdr_findbyname(struct relayd *env, const char *name) { struct rdr *rdr; TAILQ_FOREACH(rdr, env->sc_rdrs, entry) if (strcmp(rdr->conf.name, name) == 0) return (rdr); return (NULL); } struct relay * relay_findbyname(struct relayd *env, const char *name) { struct relay *rlay; TAILQ_FOREACH(rlay, env->sc_relays, rl_entry) if (strcmp(rlay->rl_conf.name, name) == 0) return (rlay); return (NULL); } void event_again(struct event *ev, int fd, short event, void (*fn)(int, short, void *), struct timeval *start, struct timeval *end, void *arg) { struct timeval tv_next, tv_now, tv; if (gettimeofday(&tv_now, NULL) == -1) fatal("event_again: gettimeofday"); bcopy(end, &tv_next, sizeof(tv_next)); timersub(&tv_now, start, &tv_now); timersub(&tv_next, &tv_now, &tv_next); bzero(&tv, sizeof(tv)); if (timercmp(&tv_next, &tv, >)) bcopy(&tv_next, &tv, sizeof(tv)); event_set(ev, fd, event, fn, arg); event_add(ev, &tv); } int expand_string(char *label, size_t len, const char *srch, const char *repl) { char *tmp; char *p, *q; if ((tmp = calloc(1, len)) == NULL) { log_debug("expand_string: calloc"); return (-1); } p = q = label; while ((q = strstr(p, srch)) != NULL) { *q = '\0'; if ((strlcat(tmp, p, len) >= len) || (strlcat(tmp, repl, len) >= len)) { log_debug("expand_string: string too long"); return (-1); } q += strlen(srch); p = q; } if (strlcat(tmp, p, len) >= len) { log_debug("expand_string: string too long"); return (-1); } (void)strlcpy(label, tmp, len); /* always fits */ free(tmp); return (0); } void translate_string(char *str) { char *reader; char *writer; reader = writer = str; while (*reader) { if (*reader == '\\') { reader++; switch (*reader) { case 'n': *writer++ = '\n'; break; case 'r': *writer++ = '\r'; break; default: *writer++ = *reader; } } else *writer++ = *reader; reader++; } *writer = '\0'; } char * digeststr(enum digest_type type, const u_int8_t *data, size_t len, char *buf) { switch (type) { case DIGEST_SHA1: return (SHA1Data(data, len, buf)); break; case DIGEST_MD5: return (MD5Data(data, len, buf)); break; default: break; } return (NULL); } const char * canonicalize_host(const char *host, char *name, size_t len) { struct sockaddr_in sin4; struct sockaddr_in6 sin6; u_int i, j; size_t plen; char c; if (len < 2) goto fail; /* * Canonicalize an IPv4/6 address */ if (inet_pton(AF_INET, host, &sin4) == 1) return (inet_ntop(AF_INET, &sin4, name, len)); if (inet_pton(AF_INET6, host, &sin6) == 1) return (inet_ntop(AF_INET6, &sin6, name, len)); /* * Canonicalize a hostname */ /* 1. remove repeated dots and convert upper case to lower case */ plen = strlen(host); bzero(name, len); for (i = j = 0; i < plen; i++) { if (j >= (len - 1)) goto fail; c = tolower(host[i]); if ((c == '.') && (j == 0 || name[j - 1] == '.')) continue; name[j++] = c; } /* 2. remove trailing dots */ for (i = j; i > 0; i--) { if (name[i - 1] != '.') break; name[i - 1] = '\0'; j--; } if (j <= 0) goto fail; return (name); fail: errno = EINVAL; return (NULL); } struct protonode * protonode_header(enum direction dir, struct protocol *proto, struct protonode *pk) { struct protonode *pn; struct proto_tree *tree; if (dir == RELAY_DIR_RESPONSE) tree = &proto->response_tree; else tree = &proto->request_tree; pn = RB_FIND(proto_tree, tree, pk); if (pn != NULL) return (pn); if ((pn = (struct protonode *)calloc(1, sizeof(*pn))) == NULL) { log_warn("out of memory"); return (NULL); } pn->key = strdup(pk->key); if (pn->key == NULL) { log_warn("out of memory"); return (NULL); } pn->value = NULL; pn->action = NODE_ACTION_NONE; pn->type = pk->type; SIMPLEQ_INIT(&pn->head); if (dir == RELAY_DIR_RESPONSE) pn->id = proto->response_nodes++; else pn->id = proto->request_nodes++; if (pn->id == INT_MAX) { log_warnx("too many protocol " "nodes defined"); return (NULL); } RB_INSERT(proto_tree, tree, pn); return (pn); } int protonode_add(enum direction dir, struct protocol *proto, struct protonode *node) { struct protonode *pn, *proot, pk; struct proto_tree *tree; if (dir == RELAY_DIR_RESPONSE) tree = &proto->response_tree; else tree = &proto->request_tree; if ((pn = calloc(1, sizeof (*pn))) == NULL) { log_warn("out of memory"); return (-1); } bcopy(node, pn, sizeof(*pn)); pn->key = node->key; pn->value = node->value; SIMPLEQ_INIT(&pn->head); if (dir == RELAY_DIR_RESPONSE) pn->id = proto->response_nodes++; else pn->id = proto->request_nodes++; if (pn->id == INT_MAX) { log_warnx("too many protocol nodes defined"); free(pn); return (-1); } if ((proot = RB_INSERT(proto_tree, tree, pn)) != NULL) { /* * A protocol node with the same key already * exists, append it to a queue behind the * existing node-> */ if (SIMPLEQ_EMPTY(&proot->head)) SIMPLEQ_NEXT(proot, entry) = pn; SIMPLEQ_INSERT_TAIL(&proot->head, pn, entry); } if (node->type == NODE_TYPE_COOKIE) pk.key = "Cookie"; else if (node->type == NODE_TYPE_URL) pk.key = "Host"; else pk.key = "GET"; if (node->type != NODE_TYPE_HEADER) { pk.type = NODE_TYPE_HEADER; pn = protonode_header(dir, proto, &pk); if (pn == NULL) return (-1); switch (node->type) { case NODE_TYPE_QUERY: pn->flags |= PNFLAG_LOOKUP_QUERY; break; case NODE_TYPE_COOKIE: pn->flags |= PNFLAG_LOOKUP_COOKIE; break; case NODE_TYPE_URL: if (node->flags & PNFLAG_LOOKUP_URL_DIGEST) pn->flags |= node->flags & PNFLAG_LOOKUP_URL_DIGEST; else pn->flags |= PNFLAG_LOOKUP_DIGEST(0); break; default: break; } } return (0); } int protonode_load(enum direction dir, struct protocol *proto, struct protonode *node, const char *name) { FILE *fp; char buf[BUFSIZ]; int ret = -1; struct protonode pn; bcopy(node, &pn, sizeof(pn)); pn.key = pn.value = NULL; if ((fp = fopen(name, "r")) == NULL) return (-1); while (fgets(buf, sizeof(buf), fp) != NULL) { /* strip whitespace and newline characters */ buf[strcspn(buf, "\r\n\t ")] = '\0'; if (!strlen(buf) || buf[0] == '#') continue; pn.key = strdup(buf); if (node->value != NULL) pn.value = strdup(node->value); if (pn.key == NULL || (node->value != NULL && pn.value == NULL)) goto fail; if (protonode_add(dir, proto, &pn) == -1) goto fail; pn.key = pn.value = NULL; } ret = 0; fail: if (pn.key != NULL) free(pn.key); if (pn.value != NULL) free(pn.value); fclose(fp); return (ret); } int bindany(struct ctl_bindany *bnd) { int s, v; s = -1; v = 1; if (relay_socket_af(&bnd->bnd_ss, bnd->bnd_port) == -1) goto fail; if ((s = socket(bnd->bnd_ss.ss_family, bnd->bnd_proto == IPPROTO_TCP ? SOCK_STREAM : SOCK_DGRAM, bnd->bnd_proto)) == -1) goto fail; if (setsockopt(s, SOL_SOCKET, SO_BINDANY, &v, sizeof(v)) == -1) goto fail; if (bind(s, (struct sockaddr *)&bnd->bnd_ss, bnd->bnd_ss.ss_len) == -1) goto fail; return (s); fail: if (s != -1) close(s); return (-1); } int map6to4(struct sockaddr_storage *in6) { struct sockaddr_storage out4; struct sockaddr_in *sin4 = (struct sockaddr_in *)&out4; struct sockaddr_in6 *sin6 = (struct sockaddr_in6 *)in6; bzero(sin4, sizeof(*sin4)); sin4->sin_len = sizeof(*sin4); sin4->sin_family = AF_INET; sin4->sin_port = sin6->sin6_port; bcopy(&sin6->sin6_addr.s6_addr[12], &sin4->sin_addr.s_addr, sizeof(sin4->sin_addr)); if (sin4->sin_addr.s_addr == INADDR_ANY || sin4->sin_addr.s_addr == INADDR_BROADCAST || IN_MULTICAST(ntohl(sin4->sin_addr.s_addr))) return (-1); bcopy(&out4, in6, sizeof(*in6)); return (0); } int map4to6(struct sockaddr_storage *in4, struct sockaddr_storage *map) { struct sockaddr_storage out6; struct sockaddr_in *sin4 = (struct sockaddr_in *)in4; struct sockaddr_in6 *sin6 = (struct sockaddr_in6 *)&out6; struct sockaddr_in6 *map6 = (struct sockaddr_in6 *)map; if (sin4->sin_addr.s_addr == INADDR_ANY || sin4->sin_addr.s_addr == INADDR_BROADCAST || IN_MULTICAST(ntohl(sin4->sin_addr.s_addr))) return (-1); bcopy(map6, sin6, sizeof(*sin6)); sin6->sin6_len = sizeof(*sin6); sin6->sin6_family = AF_INET6; sin6->sin6_port = sin4->sin_port; bcopy(&sin4->sin_addr.s_addr, &sin6->sin6_addr.s6_addr[12], sizeof(sin4->sin_addr)); bcopy(&out6, in4, sizeof(*in4)); return (0); }